Covalently bridged insulin dimers

ABSTRACT

The invention provides an analogue of a pharmaceutical active whose molecular weight is less than 25,000 Daltons, the analogue comprising a pharmaceutical active whose molecular weight is less than 25,000 Daltons covalently linked to a pendant molecular group wherein as a result of the administration of the composition to the human or animal body an active complex having a molecular weight of 25,000 Daltons or greater is present in the human or animal circulatory system. The analogue is hepatoselective when administered to the circulatory system. Preferably the analogue is an insulin analogue comprising an insulin or functional equivalent thereof covalently linked to the pendant molecular group wherein the active complex is an insulin complex. Such an insulin analogue may be used in a method of insulin replacement therapy.

DESCRIPTION

[0001] The invention relates to novel insulin analogues and to a pharmaceutical comprising such insulin analogues, a process for producing a pharmaceutical for the treatment of diabetes, and a process for the preparation of the insulin analogues.

[0002] The proteohormone insulin is produced in the β cells of the islets of Langerhans. Its most important physiological effect includes the reduction in the blood glucose level. Insulin deficiency leads to the complex pathological state of diabetes mellitus (type I) which is characterized by deviant glucose metabolism.

[0003] Diabetes mellitus is treated by employing insulin and insulin analogues in pharmaceutical preparations. In the most widely used form of therapy, the replacement therapy, insulin is administered subcutaneously. The commonest side effect of this is hypoglycemia (low blood glucose level). Despite the continuous development of pharmaceutical preparations of insulin for diabetes therapy there is a continuing search for novel insulin analogues which are promising in relation to their efficacy in combination with the reduction in side effects. Thus, for example, a fast-acting “insulin lispro” was developed (EP 0 383 472 B1) by transposing the amino acids proline^(B28) and lysine^(B29). There has likewise been development of a long-acting insulin derivative by fatty acid acylation of the ε-amino group of lysine^(B29) (J. Markussen, S. Havelund, P. Kurtzhals, A. A. Andersen, J. Halstrøm, E. Hasselager, U. D. Larsen, U. Ribel, L. Schäffer, K. Vad, I. Jonassen, Diabetologia 1996, 39, pp. 281-288). Although it is possible to influence the time course of the action of insulin by such modifications of the native structure of human insulin, considerable problems are still not solved: there is still no insulin analogue which can be used for therapy and permits, through even only partial tissue specificity, in particular hepatoselectivity, a more targeted therapy appropriate for the physiological conditions. Nor has there been disclosure of an analogue which, as a result of greater potency, could be employed in smaller amounts than human insulin or animal insulin with the native structure.

[0004] All the insulins employed for treating diabetes are always monomeric insulin molecules with a molecular mass of about 6 000. All monomeric insulin analogues and derivatives have proved to be partial or complete insulin agonists (S. Gammeltoft, Physiol. Rev. 1984, 64, p. 1321) and show a close correlation between receptor binding and triggering of the biological signal. Only in a few cases, such as, for example, in the case of covalently bridged insulin dimers, has a discrepancy between receptor binding and biological activity been observed (A Schüttler, D. Brandenburg, Hoppe Seyler's Z. Physiol. Chem. 1982, 363, pp.317-330, M. Weiland, C. Brandenburg, D. Brandenburg, H. G. Joost, Proc. Natl. Acad. Sci. USA 1990 87, pp. 1154-1158). In addition, insulin dimers have proved useful for differentiating insulin receptors in different tissues (M. Breiner, M. Weiland, W. Becker, D. Müller-Wieland, R. Streicher, M. Fabry, H. G. Joost, Molecular Pharmacology 1993, 44, pp. 271-276). They are thus of fundamental importance for diagnosis in pathological cases.

[0005] All the dimers described to date involve covalent bridging of two insulins in their native length. Insulin dimers are in principle of particular interest for therapy because they show a relative hepatoselectivity in animal experiments (demonstrated for B1,B1′-suberoyl-insulin dimer with native insulin structure, F. Shojaee-Moradie, N. C. Jackson, M. Boroujerdi, D. Brandenburg, P. H. Sönksen, R. H. Jones, Diabetologia 1995, 38, pp. 1007-1013) and thus make a more physiological reduction in the blood glucose level possible than all insulins employed at present in diabetes therapy. The B1,B1′-suberoyl-insulin dimer employed therein has, however, a considerably lower bioactivity in vitro than receptor binding (28.8% compared with 157-199%, M. A. Tatnell, R. H. Jones, K. P. Willey, A. Schüttler, D. Brandenburg, Biochem. J. 1983, 216, pp. 687-694). The ratio of bioactivity to receptor binding is thus very low at 0.15-0.18. We are not aware of an application or further development of these findings in the direction of diabetes therapy.

[0006] We have now designed and synthesized novel insulin dimers which, by reason of their properties, are promising in relation to a solution to the abovementioned problems and an improved diabetes therapy and are also referred to as insulin analogues hereinafter. In this connection, the unique feature of our approach compared with the therapy to date with monomeric insulins is that insulin analogues consisting of two identical or different insulin monomers covalently linked together via a bridge, where the insulin monomers are selected from the group comprising human insulin and animal insulins and derivatives of the aforementioned insulins, and where at least one of the two insulin monomers of an insulin analogue is a derivative, and physiologically acceptable salts thereof, are used. In particular there is use of insulin analogues in which the C termini of the B chains are truncated and modified in position B26. The insulin monomers can be bridged by substances suitable for linking proteins. Such substances and processes for linking proteins have been known for a long time. In particular, the novel insulin analogues have a bridge which is preferably located between the N-terminal amino groups of the B chains of the two insulin monomers, and which is particularly preferably formed from a linear or branched bifunctional carboxylic acid residue of the formula (CRR′)_(n)(CO—)₂ in which n, R, R′ are defined as stated below for formula I. Examples of animal insulins are the porcine, monkey, bovine and chicken insulins. Insulin derivatives are derivatives of said insulins which differ by substitution and/or deletion of at least one naturally occurring amino acid residue and/or addition of at least one amino acid residue and/or organic residue from the corresponding, otherwise identical naturally occurring insulin. One example of an insulin derivative monomer is Gly(A21), Arg(B31), Arg(B32) human insulin, and one example of the dimeric insulin analogue of the invention is B1, B1-Sub—[D—Ala^(B26)]-des-[B27-B30]-insulin-B26-amide insulin dimer. The insulin analogues can be described in particular by the general formula I:

[0007] where

[0008] X is, independently of one another, a branched or unbranched C₁-C₁₀-alkyl group, mono- or polysubstituted aryl group, C₁-C₁₀-alkyl group, mono- or polysubstituted or unsubstituted O-aryl group, an amino acid or a derivative thereof, or a group of the formula NRR′;

[0009] R,R′ is H, NH₂, a branched or unbranched C₁-C₁₀-alkyl radical or mono- or polysubstituted or unsubstituted aryl group;

[0010] n is 0, 1, 2, . . . 16.

[0011] The invention further relates to insulin analogues of the formula I as described above where X is an amino acid derivative in which the carboxylic acid group is amidated.

[0012] The invention further relates to insulin analogues of the formula I as described above where X is the amino acid sarcosine whose carboxylic acid group is amidated.

[0013] The invention further relates to insulin analogues of the formula I as described above where the X residues in the two B chains differ from one another.

[0014] The invention further relates to insulin analogues of the formula I as described above where X is an amino group.

[0015] The invention further relates to a pharmaceutical comprising such insulin analogues, a process for producing a pharmaceutical for treating diabetes, and a process for preparing the insulin analogues.

[0016] The insulin analogues are prepared in a known manner by bridging two optionally partially protected monomeric molecules with the preactivated dicarboxylic acid (A Schüttler, D. Brandenburg, Hoppe Seyler's Z. Physiol. Chem. 1982, 363, pp.317-330). The monomeric analogues can be obtained by enzyme-catalyzed semisynthesis or by methods of genetic manipulation (see examples of the invention).

[0017] The invention accordingly further relates to a process for preparing the insulin analogues as described above, where

[0018] (a) the monomeric insulin analogues are obtained by enzyme-catalyzed semisynthesis or by methods of genetic manipulation,

[0019] (b) the monomeric insulin analogues from step (a) are optionally partially protected by protective groups;

[0020] (c) the protected monomeric insulin analogues from step (b) and/or the monomeric insulin analogues from step (a) are reacted with a preactivated dicarboxylic acid, and

[0021] (d) the insulin analogues obtained in step (c) are isolated from the reaction mixture.

[0022] Compared with human insulin and monomeric insulin analogues, the dimers of the invention are distinguished by particularly high affinity for insulin receptors and superpotency in vitro, the latter up to twenty times the insulin effect.

[0023] In contrast to previously disclosed covalent insulin dimers, the novel dimers show very high bioactivities. The ratio of bioactivity to receptor binding is at least 2, and in some cases even 4 to 5. They are thus considerably more biologically effective. Comparison of these quotients with those described in the literature for B1,B1′-suberoyl dimers reveals a factor of at least 11 (0.18:2), and a maximum of 28.

[0024] The advantages achieved with the insulin dimers of the invention are, in particular, that

[0025] 1. compared with insulin and all analogues employed therapeutically at present there is expected to be a relative hepatoselectivity and thus a more physiological mode of action (primary site of action the liver and not the periphery),

[0026] 2. compared with previously disclosed insulin dimers for the first time a considerably improved biological efficacy is present,

[0027] 3. the biological activity which is considerably increased compared with insulin and monomeric analogues can prove to be very advantageous on use because an equivalent effect would be achievable with distinctly smaller amounts of active substance.

EXAMPLES OF THE INVENTION

[0028] Abbreviations AA amino acid Ac acetate (CH₃COO⁻) Alox aluminum oxide (Al₂O₃) CZE capillary zone electrophoresis DIPEA N,N-diisopropylethylamine DMF dimethylformamide DMSO dimethyl sulfoxide DOI desoctapeptide insulin Eq equivalents Fmoc 9-fluorenylmethoxycarbonyl HOBt 1-hydroxybenzotriazole HPCL high performance liquid chromotography MALDI matrix-assisted laser desorption/ionization MPLC medium pressure liquid chromotography Msc methylsulfonylethoxycarbonyl MW molecular weight NaOH sodium hydroxide NMM N-methylmorpholine RP reversed phase ONSu N-oxysuccinimide ester Sar sarcosine Sub suberoyl TBTU 2-(1H-benzotriazol-1-yl)-1,1,3,3-tetramethyluronium tetrafluoroborate TEA triethylamine TFA trifluoroacetic acid TOF time of flight TPCK tosyl-L-phenylalanyl chloromethyl ketone Tris tris-(hydroxymethyl)aminomethane

Example 1 of the Invention Synthesis of B1,B1′-Sub—[Sar^(B26)]-des-(B27-B30)-insulin-B26-amide insulin dimer Synthesis of the tetrapeptide Gly—Phe—Phe—Sar—NH₂

[0029] The peptide was synthesized on a 4-(2′,4′-dimethoxyphenyl-Fmoc-aminomethyl)phenoxy resin using the Fmoc protective group tactic. The Fmoc-amino acid esters used for the coupling were formed by the TBTU/HOBt method and employed in a 3-molar excess based on the nominal loading of the resin. The peptide was synthesized in accordance with the following synthesis protocol: Reagents/ No. Operation solvents Duration Repeats 1 Swelling of the DMF   1 min. once resin 2 Elimination of the 20% piperidine   6 min. three times Fmoc group in DMF 3 Washing DMF 0.5 min three times 4 Washing 2-propanol 0.5 min. twice 5 Kaiser test* 6 Swelling of the DMF   1 min. once resin 7 Coupling of the 3 Eq. Fmoc-AA,  45 min. once AA 3 eq. each TBTU, HOBt and 4.5 eq. NMM in 5 ml DMF 8 Washing DMF 0.5 min. three times 9 Washing 2-propanol 0.5 min. twice 10 Kaiser test* 11 Swelling of the DMF   1 min. once resin 12 Blocking of 400 μl Ac₂O and once unreacted amino 200 μl DIPEA in  10 min. end groups 5 ml DMF 13 Washing DMF 0.5 min. 14 Washing 2-propanol 0.5 min.

[0030] The peptide was eliminated from the resin by acidolysis through addition of 10 ml of the elimination solution composed of 95% TFA, 4% H₂O and 1% triethylsilane as cation trap. After stirring at room temperature for 2 h, the resin was filtered off and thoroughly washed with dichloromethane. The filtrate was evaporated to dryness.

[0031] Further purification of the peptide took place by RP-MPLC column chromatography with a linear 2-propanol gradient (0-40% 2-propanol in 400 ml of each of 0.07% TFA starting buffer and feed buffer). Nucleosil 20-C₁₈ was used as stationary phase. The flow rate was 180-200 ml/h (82.6% yield).

Semisynthesis of [Sar^(B26)]-des-(B27-B30)-insulin-B26-amide

[0032] The insulin with truncated C terminus of the B chain was synthesized by enzymatic coupling of the tetrapeptide to N^(αA1)—Msc-des-(B23-B30)-insulin. For this purpose it was initially necessary to degrade native insulin enzymatically to DOI, which was then partially provided with a protective group.

Synthesis of des-(B23-B30)-insulin

[0033] 300 mg (51.66 μmol) of insulin are taken up in 60 ml of reaction buffer (0.05 M Tris, 1 mmol CaCl₂). After the pH has been adjusted to 9.5 with solid Tris, the proteolytic degradation is started by adding 16 mg of TPCK-treated trypsin. Incubation is carried out in a water bath at 37° C. for about 6 h, the reaction being monitored by RP-HPLC. The reaction is stopped by adding 4 ml of glacial acetic acid, and the reaction mixture is concentrated in a rotary evaporator. Working up takes place by initial Sephadex G 25f gel filtration and subsequent Sephadex G 50f gel filtration. The product is lyophilized (73.3% yield). MW: 4865

Synthesis of N^(αA1)—(Msc)-des-(B23-B30)-insulin

[0034] 300 mg (61.66 μmol) of des-(B23-B30)-insulin are dissolved in 22.5 ml of DMSO with the addition of 225 μl of TEA. While stirring gently, a solution of 18 mg (67.86 μmol) of Msc—ONSu in 5 ml of DMSO is added. After a reaction time of 20 min, the reaction is stopped by adding 750 μl of glacial acetic acid, and the reaction solution is dialyzed against demineralized water at 4° C. for 16 h. The retentate is freeze-dried. For further purification, an ion-exchange chromatography is carried out on SP-Sepharose (pH 3; 350 ml of starting buffer, 350 ml of 0.09 M NaCl feed buffer) and desalting is carried out on Sephadex G 25f. The product is lyophilized (30.8% yield). MW: 5015.16

Tryptic coupling of Gly—Phe—Phe—Sar—NH₂ to N^(αA1)—(Msc)-des-(B23-B30)-insulin

[0035] 132.75 mg (300 μmol) of Gly—Phe—Phe—Sar—NH₂ and 150.45 mg (30 μmol) of N^(αA1)—Msc-des-(B23-B30)-insulin are dissolved or suspended in 2 ml of DMF (stirred over Alox), 2 ml of 1,4-butanediol and 400 μl of 0.05 M Ca(CH₃COO)₂ solution. The apparent pH is adjusted to 6.7-7.0 with NMM. Subsequently 23 mg of TPCK-treated trypsin, dissolved in 100 μl of 0.05 M Ca(CH₃COO)₂ solution, are added to the reaction mixture. During the reaction time, the progress of the reaction is followed by RP-HPLC and the pH is checked and readjusted where appropriate with NMM. A conversion of almost 90% can be achieved after 4.5 h. The reaction is stopped by adding 4.5 ml of 30% strength acetic acid. The enzyme, the peptide and other low molecular weight substances are removed by Sephadex G 50f gel chromatography. Unreacted peptide is subsequently purified by RP-MPLC and recovered. Further purification of the insulin derivative takes place by preparative RP-HPCL on a Nucleosil 100-10C₈ (2.0 cm diameter, 25.0 cm length with a 5.0 cm precolumn (48.6% yield). MW: 5290.2

Synthesis of B1,B1′-Sub—[Sar^(B26)]-des-(B27-B30)-insulin-B26-amide insulin dimer

[0036] 100 mg (18.9 μmol) of N^(αA1)—Msc—[Sar^(B26)]-des-(B27-B30)-insulin-B26-amide are dissolved in 400 μl of DMSO, 8.7 μl of DMF and 9.5 μl of NMM with the addition of 5.5 equivalents of HOBt. After 30 min, 0.6 equivalents of suberic acid bis-ONSu ester is added in solid form and stirred for 8-30 h. The entire reaction mixture is taken in 1.5 ml of 10% strength acetic acid with the addition of 300 μl of glacial acetic acid and chromatographed on Sephadex G 50f. The dimer fraction is lyophilized. To eliminate the Msc groups, 100 mg of Msc-protected protein are dissolved in 5 ml of a dioxane/water mixture (2/1, v/v) and cooled to 0° C. 514 μl of 2N NaOH are added and the mixture is stirred at 0° C. for 120 s. The reaction is stopped by adding 2.2 ml of glacial acetic acid. The reaction mixture is gel chromatographed on Sephadex G 25f and lyophilized (11.9% yield). The characterization of the intermediates and the final product took place by RP-HPLC, acidic CZE and MALDI-TOF mass spectrometry (Table 1).

[0037] Tab. 1: Yields, purities according to RP-HPLC, and CZE and masses in the synthesis of B1,B1′-Sub—[Sar^(B26)]-des-(B27-B30)-insulin-B26-amide insulin dimer Yield Purity [%] by MW [g/mol] Derivative [%] RP-HPLC CZE calc. meas. Gly-Phe-Phe-Sar-NH₂ 82.6 98.5 >99 442.5 463.2* A1-Msc-DOI-Gly-Phe- 48.6 95.6 >99 5441.2 5439 Phe-Sar-NH₂ B1,B1′-Sub-DOI-Gly- 14.4 90 >99 10,720 10,710 Phe-Phe-Sar-NH₂ dimer

Example 2 of the Invention Synthesis of B1,B1′-Sub—[D—Ala^(B26)]-des-(B27-B30)-insulin-B26-amide insulin dimer

[0038] Synthesis of this truncated insulin dimer took place in analogy to the synthesis described for example 1 of the invention with the exception that the synthetic tetrapeptide Gly—Phe—Phe—D—Ala—NH₂ was used. The corresponding yields, purities and masses are shown in Table 2.

[0039] Tab. 2: Yields, purities according to RP-HPLC, and CZE and masses in the synthesis of B1,B1′-Sub—[D—Ala^(B26)}-des-(B27-B30)-insulin-B26-amide insulin dimer Yield Purity [%] by MW [g/mol] Derivative [%] RP-HPLC CZE calc. meas. Gly-Phe-Phe-D-Ala- 61.6 99.1 >99 442.5 463.2* NH₂ A1-Msc-DOI-Gly-Phe- 53.9 95.1 >99 5441.2 5439.4 Phe-D-Ala-NH₂ B1,B1′-Sub-DOI-Gly- 11.9 88.1 >99 10,720 10,713 Phe-Phe-D-Ala-NH₂ dimer

Example 3 of the Invention Synthesis of B1,B1′-Sub—[Glu^(B26)}-des-(B27-B30)-insulin-B26-amide insulin dimer

[0040] Synthesis of this truncated insulin dimer took place in analogy to the synthesis described for example 1 of the invention with the exception that the synthetic tetrapeptide Gly—Phe—Phe—Glu—NH₂ was used. The corresponding yields, purities and masses are shown in Table 3.

[0041] Tab. 3: Yields, purities according to RP-HPLC, and CZE and masses in the synthesis of B1,B1′-Sub—[Glu^(B26)]-des-(B27-B30)-insulin-B26-amide insulin dimer Yield Purity [%] by MW [g/mol] Derivative [%] RP-HPLC CZE calc. meas. Gly-Phe-Phe-Glu-NH₂ 74.9 94.5 >99 449.2 498.3 A1-Msc-DOI-Gly-Phe- 38.6 95.7 >99 5498.2 5497.6 Phe-Glu-NH₂ B1,B1′-Sub-DOI-Gly- 15.8 >99 >99 10,826 10,833 Phe-Phe-Glu-NH₂ dimer

Example 4 of the Invention Biological Properties for Examples 1-3 of the Invention

[0042] The biological properties of the dimers B1,B1′-Sub—[Sar, D—Ala or Glu^(B26)]-des-(B27-B30)-insulin-B26-amide dimer, described in examples 1-3 of the invention were determined on the one hand on the basis of the receptor binding, and on the other hand on the basis of the bioactivity in vitro.

[0043] The receptor binding was determined by displacement studies on IM-9 lymphocytes. The relative biological activity was determined on cultivated 3T3-L1 adipocytes in the form of the glucose transport. Table 4 shows the binding affinities and the relative biological activities of the synthesized insulin dimers.

[0044] Tab. 4: Relative receptor binding (determined on IM-9 lymphocytes) and relative biological activities (determined on cultivated 3T3-L1 adipocytes) of all the insulin dimers compared with native insulin. Rel. receptor Rel. biol. binding activity Dimer [%] [%] B1,B1′-Sub-[Sar^(B26)]-des-(B27-B30)- 412 ± 94.8 1957 ± 575  insulin-B26-amide insulin dimer B1,B1′-Sub-[D-Ala^(B26)]-des-(B27- 357 ± 53.6 814 ± 184 B30)-insulin-B26-amide insulin dimer B1,B1′-Sub-[Glu^(B26)]-des-(B27-B30)- 176 ± 45.8 817.5 ± 224   insulin-B26-amide insulin dimer

[0045] References

[0046] 1. J. Markussen, S. Havelund, P. Kurtzhals, A. A. Andersen, J. Halstrøm, E. Hasselager, U. D. Larsen, U. Ribel, L. Schäffer, K. Vad, l. Jonassen, Diabetologia 1996, 39, pp. 281-288.

[0047] 2. European patent EP 0 383 472 B1.

[0048] 3. S. Gammeltoft, Physiol Rev. 1984, 64, p. 1321.

[0049] 4. A Schüttler, D. Brandenburg, Hoppe Seyler's Z. Physiol. Chem. 1982, 363, pp.317-330.

[0050] 5. M. Weiland, C. Brandenburg, D. Brandenburg, H. G. Joost, Proc. Natl. Acad. Sci. USA 1990 87, pp. 1154-1158.

[0051] 6. M. Breiner, M. Weiland, W. Becker, D. Müller-Wieland, R. Streicher, M. Fabry, H. G. Joost, Molecular Pharmacology 1993, 44, pp. 271-276.

[0052] 7. F. Shojaee-Moradie, N. C. Jackson, M. Boroujerdi, D. Brandenburg, P. H. Sönksen, R. H. Jones, Diabetologia 1995, 38, pp. 1007-1013.

[0053] 8. M. A. Tatnell, R. H. Jones, K. P. Willey, A. Schüttler, D. Brandenburg, Biochem. J. 1983, 216, pp. 687-694. 

1. An insulin analogue consisting of two identical or different insulin monomers covalently linked together via a bridge, where the insulin monomers are selected from a group comprising human insulin, animal insulins and derivatives of human insulin and animal insulins, and where at least one derivative of human insulin or of an animal insulin is present in an insulin analogue; and physiologically acceptable salts thereof.
 2. An insulin analogue as claimed in claim 1, characterized by formula I.

where X is, independently of one another, a branched or unbranched C₁-C₁₀-alkyl group, mono- or polysubstituted aryl group, C₁-C₁₀-alkyl group, mono- or polysubstituted or unsubstituted O-aryl group, an amino acid or a derivative thereof, or a group of the formula NRR′; R,R′ is H, NH₂, a branched or unbranched C₁-C₁₀-alkyl radical or mono- or polysubstituted or unsubstituted aryl group; n is 0, 1, 2, . . .
 16. 3. An insulin analogue as claimed in claim 2, where X is an amino acid in which the carboxylic acid group is amidated.
 4. An insulin analogue as claimed in claim 3, where X is the amino acid sarcosine.
 5. An insulin analogue as claimed in one or more of claims 2 or 3, where the X residues in the two B chains are different from one another.
 6. An insulin analogue as claimed in one or more of claims 2 or 3, where X is an amino group.
 7. B1,B1-Sub—[Sar^(B26)]-des-(B27-B30)-insulin-B26-amide insulin dimer.
 8. B1,B1-Sub—[D—Ala^(B26)]-des-(B27-B30)-insulin-B26-amide insulin dimer.
 9. B1,B1-Sub—[Glu^(B26)]-des-(B27-B30)-insulin-B26-amide insulin dimer.
 10. A pharmaceutical preparation which comprises an insulin analogue as claimed in one or more of claims 1-9 and additions selected from the group comprising zinc salts, phenol, m-cresol, glycerol and buffer substances.
 11. A process for producing a pharmaceutical for the treatment of diabetes comprising an insulin analogue as claimed in one or more of claims 1-9.
 12. An insulin analogue as claimed in one or more of claims 1-9 for use as pharmaceutical.
 13. A diagnostic kit comprising one or more insulin analogues as claimed in one or more of claims 1-9.
 14. A process for preparing the insulin analogues as claimed in one or more of claims 1-9, where (a) the monomeric insulin analogues are obtained by enzyme-catalyzed semisynthesis or by methods of genetic manipulation, (b) the monomeric insulin analogues from step (a) are optionally partially protected by protective groups; (c) the protected monomeric insulin analogues from step (b) and/or the monomeric insulin analogues from step (a) are reacted with a preactivated dicarboxylic acid, and (d) the insulin analogues obtained in step (c) are isolated from the reaction mixture. 